Biochemical characterization of an Escherichia coli hisT strain

Analysis of regulation of the ilvGMEDA operon by using leader-attenuator-galK gene fusions

Five of the genes for the biosynthesis of isoleucine and valine form the ilvGMEDA operon of Escherichia coli K-12. Expression of the operon responds to changes in the availability of isoleucine, leucine, and valine (ILV). Addition of an excess of all three amino acids results in reduced expression of the operon, whereas limitation for one of the three amino acids causes an increase in expression. The operon is preceded by a leader-attenuator which clearly regulates the increased expression that occurs due to reduced aminoacylation of tRNA. To assess the factors that result in the reduced expression of this operon upon the addition of ILV, a series of plasmids were constructed in which the ilv regulatory region was fused to galK. In response to addition of the amino acids, expression of the galK gene fused to the leader-attenuator decreased five- to sevenfold, instead of the twofold observed for the chromosomal operon. A deletion analysis with these plasmids indicated that the ILV-specific decrease in expression required an intact leader-attenuator but not ilvGp2 or the DNA that precedes this promoter. This conclusion was supported by both S1 nuclease analysis of transcription initiation and determination of galK mRNA levels by RNA-RNA hybridization.

Physical identification of an internal promoter, ilvAp, in the distal portion of the ilvGMEDA operon

It has been previously demonstrated that the ilvGMEDA operon is expressed in vivo from the promoters ilvGp2 and ilvEp. An additional internal promoter is identified and designated ilvAp. This internal promoter, which allows independent expression of ilvA, has been analyzed both in vivo and in vitro. Our results indicate that: (1) ilvAp exists in both Escherichia coli K-12 and Salmonella typhimurium, as demonstrated by fusion to the galK reporter gene; (2) ilvAp is located in the distal coding sequence of ilvD; (3) the ilvAp sequences are not identical for these two bacterial species; (4) transcription from ilvAp of E. coli K-12 was demonstrated; (5) expression from ilvAp responds to the availability of oxygen; (6) potential 3' 5'-cyclic AMP receptor protein binding sites exist adjacent to ilvAp.

Point mutations in the regulatory region of the ilvGMEDA operon of Escherichia coli K-12

The ilvGMEDA operon of Escherichia coli K-12 is preceded by a regulatory region containing a promoter, a leader, and an attenuator. This region has been extensively characterized biochemically. In this note point mutations of the regulatory region are reported. The effect of these mutations on expression from the ilv regulatory region supports the previous biochemical analysis.

Translational coupling between the ilvD and ilvA genes of Escherichia coli

The hypothesis that translation of the ilvD and ilvA genes of Escherichia coli may be linked has been examined in strains in which lacZ-ilvD protein fusions are translated in all three reading frames with respect to ilvD. In these strains, the nucleotide sequence was altered to obtain premature termination of ilvD translation, and in one strain translation termination of ilvD DNA occurred two bases downstream of the ilvA initiation codon. In the wild-type strain, the ilvD translation termination site was located two bases upstream of the ilvA start codon. In each of the mutant strains, expression of ilvA, as determined by the level of threonine deaminase activity, was strikingly lower than in the wild-type strain. The data suggest that expression of ilvD and ilvA is translationally coupled. By inserting a promoterless cat gene downstream of ilvA, it was shown that the differences in enzyme activity were not the result of differences in the amount of ilvA mRNA produced.

Inaccurate protein synthesis in a mutant of Salmonella typhimurium defective in transfer RNA pseudouridylation

Protein synthesis was studied comparatively in a wild-type strain of Salmonella typhimurium and in hisT mutant cells defective in the pseudouridylation of transfer RNA. From a quantitative point of view, no significant differences between the two types of strain was observed when measuring the rate of protein synthesis during either exponential growth or starvation for histidine. In contrast, the qualitative analysis of proteins by two-dimensional gel electrophoresis showed that histidine-starved hisT cells mistranslate the genetic program at a higher frequency than exponentially growing hisT cells or either starved or unstarved hisT+ cells.

Specificity of the attenuation response of the threonine operon of Escherichia coli is determined by the threonine and isoleucine codons in the leader transcript

Expression of the threonine (thr) operon enzymes of Escherichia coli is regulated by an attenuation mechanism. The regulatory portion of the operon contains a region coding for a leader peptide that contains consecutive threonine and isoleucine codons. It is thought that translation of the leader peptide controls the frequency of transcription termination at the attenuator site. Using oligonucleotide-directed site-specific mutagenesis we have altered the putative control codons of the leader peptide coding region. In two of the mutants the threonine and isoleucine codons were changed to produce peptides containing histidine and tyrosine codons. Both mutants showed loss of regulation by threonine and isoleucine. A hisT mutation, which leads to an undermodification of tRNA(His), increased thr operon expression in the mutants threefold but did not affect expression of the wild-type thr operon. Two other mutants were constructed that contained two histidine codons early in the leader peptide. Expression in both of these mutants was unaltered by the presence of the hisT allele or by the addition of threonine and isoleucine to the growth medium. In addition, a wild-type strain containing a temperature-sensitive threonyl-tRNA synthetase mutation showed increased thr operon expression at the non-permissive temperature, whereas none of the mutants showed any change. Taken together these data indicate that the specificity of the attenuation response is effected by specific control codons within the thr leader peptide coding region. We have also directly demonstrated thr leader peptide synthesis in vitro using a plasmid encoding the wild-type thr leader region to direct the synthesis of a peptide of the appropriate molecular weight when labeled with [3H]threonine but not with [3H]histidine or [3H]tyrosine. Conversely, when extracts were incubated with templates containing the mutated DNAs, peptides were labeled that showed patterns consistent with the expected amino acid compositions. These data indicate that the thr leader RNA is translated into the predicted leader peptide.

Actions of the anticodon arm in translation on the phenotypes of RNA mutants

In previous publications, we have shown that it is practical to study the translational activity of tRNAs by replacement and alteration of the anticodon arm sequence of the genus on a plasmid clone. Experiments in which the anticodon arm sequence is transplanted between tRNA genes suggest that the translational activity is determined by these sequences. We have therefore made every variant of the anticodon loop and the three base-pairs of the stem proximal to the loop, in order to resolve the relation between the structure of Su7Am tRNATrp, and its function. All derivatives conserved the normal secondary structure of the molecule, which was known to be essential for translational activity. The probability of translation of the amber codon by these suppressors is measured in this work. This translational activity in vivo is rationalized in terms of data on the copy numbers of the plasmid clones, the nucleotide modifications of the tRNAs, the steady-state level of the mature tRNA, and the aminoacylation of these molecules. Nucleotide modification levels vary among these tRNAs, giving information about the specificities of modification systems that make O-methylribose, pseudouridine, and modified A in the anticodon arm. However, for this series of tRNAs, none of these modifications has a strong effect on translational efficiency of the tRNAs. A few of the substitutions reduce aminoacylation of the tRNAs with glutamine, as determined by comparison of suppression in normal strains and related strains, which have 25-fold elevated levels of the glutaminyl-tRNA synthetase (GlnRS). The substitutions that have the largest effect on GlnRS action are, unexpectedly, purines for conserved pyrimidines on the 5' side of the anticodon loop. Data on the concentrations of tRNA in vivo suggest that the anticodon loop and helix contribute similarly to the determination of the steady-state level of the tRNAs. This level varies sevenfold, though all tRNAs are processed from a homologous precursor made from the same transcription unit. Effects on levels appear to be mediated by changes in anticodon arm structure. A robust equation that relates aminoacyl-tRNA levels to suppressor efficiency is developed in order to resolve effects on tRNA levels and on ribosomal steps: E = A/(K + A), where E is efficiency, A is aminoacyl-tRNA concentration, and K is the effective concentration, or cellular tRNA content required for an individual tRNA to have an efficiency of 0.50. The tRNAs vary in their intrinsic ability to function on the ribosome (represented by K), after other influences have been normalized.(ABSTRACT TRUNCATED AT 400 WORDS)

Escherichia coli B/r leuK mutant lacking pseudouridine synthase I activity

Escherichia coli B/r strain EB146 containing mutation leuK16 has elevated levels of enzymes involved in the synthesis of leucine, valine, isoleucine, histidine, and tryptophan (Brown et al., J. Bacteriol. 135:542-550, 1978). We show here that strain EB146 (leuK16) has properties that are similar to those of E. coli and Salmonella typhimurium hisT strains. In tRNA1Leu from both hisT and leuK strains, positions 39 and 41 are uridine residues rather than pseudouridine residues. Furthermore, in tRNA3Leu and tRNA4Leu from a leuK strain, uridine residues at positions 39 and 40, respectively, are unmodified. Pseudouridine synthase I activity is missing in extracts of strain EB146 (leuK16), and extracts of strain EB146 (leuK16) and of a hisT strain do not complement one another in vitro. Four phenotypes of strain EB146 (leuK16), leucine excretion, wrinkled colony morphology, and elevated levels of leu and his enzymes, are complemented by a plasmid having a 1.65-kilobase DNA fragment containing the E. coli K-12 hisT locus. These results indicate that either leuK codes for pseudouridine synthase I (and is thus a hisT locus in reality) or, less likely, it codes for a product that affects the synthesis or activity of pseudouridine synthase I.

Analysis and comparison of the internal promoter, pE, of the ilvGMEDA operons from Escherichia coli K-12 and Salmonella typhimurium

It was previously determined that the distal portion of the ilvGMEDA operon was expressed despite the insertion of transposons into ilvG and ilvE. This observation suggested the existence of internal promoters upstream of ilvE (pE) and ilvD (pD). The internal promoter pE, responsible for part of ilvEDA expression, has been analyzed both in vivo and in vitro. Our results indicate that: pE exists in both E. coli K-12 and S. typhimurium; pE is located in the distal end of the ilvM coding sequence; the pE sequence is highly conserved in the two bacteria; the amino acid sequence of the ilvM gene product is 93% homologous between the two bacteria; transcription from pE can be demonstrated both in vivo and in vitro; the efficiency of pE is essentially equivalent in the two bacteria.

Physical analysis of deletion mutations in the ilvGEDA operon of Escherichia coli K-12

DNA-DNA hybridization of cloned segments of the Escherichia coli K-12 ilvGEDA operon to genomic blots was used to determine the physical dimensions of a series of deletion mutations of the ilvGEDA operon. The smallest mutation resulted from the deletion of approximately 200 base pairs from within ilvD, whereas the largest mutation resulted from the deletion of 17 kilobases including the rep gene. The structure of three of these mutants indicates that formation of the deletions was mediated by Tn5 (or Tn5-131) that is retained in the chromosome. This is the first observation of this type of Tn5-mediated event. Our analysis of the total acetohydroxy acid synthase activity of strains containing deletions of ilvG indicates that the truncated ilvG polypeptide of wild-type E. coli K-12 lacks enzyme activity. The small 200-base-pair deletion of ilvD confirms the presence of a strong polar site 5' to ilvA. The detailed structure of these deletions should prove useful for the investigation of other genes in this region. This genomic analysis demonstrates that the ilv restriction site map that was established previously by the analysis of recombinant bacteriophage and plasmids is identical to that on the genome.

hisT is part of a multigene operon in Escherichia coli K-12

The Escherichia coli K-12 hisT gene has been cloned, and its organization and expression have been analyzed on multicopy plasmids. The hisT gene, which encodes tRNA pseudouridine synthase I (PSUI), was isolated on a Clarke-Carbon plasmid known to contain the purF gene. The presence of the hisT gene on this plasmid was suggested by its ability to restore both production of PSUI enzymatic activity and suppression of amber mutations in a hisT mutant strain. A 2.3-kilobase HindIII-ClaI restriction fragment containing the hisT gene was subcloned into plasmid pBR322, and the resulting plasmid (designated psi 300) was mapped with restriction enzymes. Complementation analysis with different kinds of hisT mutations and tRNA structural analysis confirmed that plasmid psi 300 contained the hisT structural gene. Enzyme assays showed that plasmid psi 300 overproduced PSUI activity by ca. 20-fold compared with the wild-type level. Subclones containing restriction fragments from plasmid psi 300 inserted downstream from the lac promoter established that the hisT gene is oriented from the HindIII site toward the ClaI site. Other subclones and derivatives of plasmid psi 300 containing insertion or deletion mutations were constructed and assayed for production of PSUI activity and production of proteins in minicells. These experiments showed that: (i) the proximal 1.3-kilobase HindIII-BssHII restriction fragment contains a promoter for the hisT gene and encodes a 45,000-dalton polypeptide that is not PSUI; (ii) the distal 1.0-kilobase BssHII-ClaI restriction fragment encodes the 31,000-dalton PSUI polypeptide; (iii) the 45,000-dalton polypeptide is synthesized in an approximately eightfold excess compared with PSUI; and (iv) synthesis of the two polypeptides is coupled, suggesting that the two genes are part of an operon. Insertion of mini-Mu d1 (lac Km) phage into plasmid psi 300 confirmed that the hisT gene is the downstream gene in the operon.

Nucleotide sequence of the ilvB multivalent attenuator region of Escherichia coli K12

The ilvB gene of Escherichia coli K12 has been cloned into a multicopy plasmid. The regulation of the cloned gene by valine or leucine limitation and by catabolite repression is the same as for the chromosome encoded gene. The nucleotide sequence of a regulatory region preceding the ilvB structural gene has been determined. This DNA sequence includes a promoter, a region which codes for a putative 32 amino acid polypeptide containing multiple valine and leucine codons, and a transcription termination site. In vitro transcription of this region produces a 184 nucleotide terminated leader transcript. Mutually exclusive secondary structures of the leader transcript are predicted. On the basis of these data, a model for multivalent attenuation of the ilvB operon is presented. Data are presented which suggests that at least part of the postulated CRP-cyclic AMP binding site of the ilvB operon precedes the transcription start site by more than 71 base pairs.

Specific mistranslation in hisT mutants of Escherichia coli

Certain strains of Escherichia coli mistranslate at very high frequencies when starved for asparagine or histidine. This mistranslation is the result of misreading events on the ribosome. The introduction of a hisT mutation into such a strain decreases the frequency of mistranslation during histidine starvation but not during asparagine starvation. The most likely explanation is that the replacement of the pseudouridine residue in the anticodon loop of glutamine specific transfer ribonucleic acid by uridine in hisT mutants leads to an increase in fidelity of transfer ribonucleic acid function. The hisT gene in Escherichia coli has also been more accurately mapped, giving the gene order purF-hisT-aroC-fadL-dsdA.

Strains of Escherichia coli carrying the structural gene for histidyl-tRNA synthetase on a high copy-number plasmid

That portion of the Escherichia coli chromosome carried by a number of lambda transducing phages, all of which carry the gua operon, was mapped using restriction endonucleases. The DNA from one of these transducing phages was subcloned onto pBR322. We have identified two recombinant plasmids which carry the Escherichia coli gene hisS, the structural gene for histidyl-tRNA synthetase. The two plasmids, pSE301 and pSE401, have in common a 3,540 bp fragment of E. coli DNA which is bounded by BglII and SalI restriction endonuclease recognition sites. Strains carrying these plasmids overproduce histidyl-tRNA synthetase 20 to 30 fold. The growth rate of these strains is not affected although the histidine biosynthetic enzymes are derepressed. This derepression seems to be in addition to that caused by introduction of a hisT mutation on the chromosome.

Multivalent translational control of transcription termination at attenuator of ilvGEDA operon of Escherichia coli K-12

The regulatory region for the ilvGEDA operon of Escherichia coli K-12 has been located and characterized. ilv leader RNA transcribed from this region is described, and the DNA sequence of the region is presented. This DNA sequence contains a transcription promoter, a region coding for a 32-amino-acid polypeptide containing multiple isoleucine, valine, and leucine codons, and a transcription termination site preceding the first structural gene. The mutually exclusive secondary structures of the leader RNA have been analyzed. On the basis of these data, a model for the multivalent attenuation of the ilvGEDA operon is proposed.

The relA locus specifies a positive effector in branched-chain amino acid transport regulation

The regulation of branched-chain amino acid transport and periplasmic binding proteins was studied in Escherichia coli strains which were isogenic except for the relA locus, the gene for the "stringent factor," which is responsible for guanosine tetraphosphate synthesis. The strain containing the relA mutation could not be derepressed for the synthesis of leucine transport or binding proteins when shifted from a medium containing all 20 amino acids in excess to one in which leucine was limiting. The relA+ strain showed normal derepression under these conditions.

Effects of altered rho gene product on the expression of the Escherichia coli histidine operon

An altered rho gene product affects expression of the his operon of Escherichia coli. The effect is greater for the operator proximal portion of the his operon than for the operator distal portion. This "rho effect" appears to be independent of the site of action of hisT-altered histidyl-tRNA.

A site of action for tRNA mediated regulation of the ilvOEDA operon of Escherichia coli K12

Transfer RNA (tRNA), rho factor threonine deaminase and the ilvO locus are molecular participants in the regulation of isoleucine-valine (ilv) biosynthesis. Isogenic strains have been constructed with the hisT76 mutation in pairwise combination with ilvO mutations, the rho221 mutation and the ilvDAC115 deletion mutation. The role of the altered tRNA of the hisT76 mutation was found to be independent of the sites of action of the ilvO- mutation, rho factor, and threonine deaminase. The expression of the ilvOEDA operon is stimulated 2-fold when the hisT76 mutation is present in strains containing either ilvO- or rho221 mutations. The expression of the ilvOEDA operon remains nonrepressed in a hisT76 strain deleted for threonine deaminase. These results indicate that the hisT76 undermodified tRNAs are influencing the initiation of transcription of the ilvOEDA operon.

Correlation between the serine sensitivity and the derepressibility of the ilv genes in Escherichia coli relA- mutants

Upon addition of excess one carbon metabolites (including serine)bacteria stop growing because of isoleucine starvation. After such treatment stringent bacteria rapidly resume normal growth whereas relaxed mutants remain unable for some time to grow. We show here that this is due to a lack of derepressibility of ilv genes after the starvation period. Results are also presented which show that RNA polymerase structural mutants may be selected among the clones resistant to a mixture of serine, methionine and glycine, in relA- strains. Finally circumstancial evidence suggests that the one carbon metabolism may be involved in a process controlling isoleucine metabolism.

Expression of the histidine operon in rho mutants of Escherichia coli

Expression of the Escherichia coli histidine operon was measured in four independently isolated sets of strains carrying ten different rho mutations. Rho factor does not act as a major regulatory element of histidine operon attenuation.

Branched-chain amino acid transport regulation in mutants blocked in tRNA maturation and transcriptional termination

The regulation of branched-chain amino acid transport and binding protein biosynthesis was studied in Escherichia coli strains containing hisT (the structural gene for pseudouridine synthetase) and rho (the structural gene for the mRNA transcriptional termination factor rho) mutations. The results indicate that the hisT strain cannot be fully derepressed for transport and that the hisT rho double mutant is partially derepressed under excess leucine conditions, but cannot be further derepressed by leucine deprivation. These data are consistent with a model in which fully mature tRNALeu is required for derepression and in which rho interacts with tRNALeu in regulating transport by terminating transcription, especially in excess-leucine growth conditions.

Repression of Escherichia coli pyridine nucleotide transhydrogenase by leucine

Addition of 0.1% casein hydrolysate to a minimal growth medium decreased membrane-bound transhydrogenase activity in Escherichia coli by about 80%. Of the amino acids added individually to the growth medium, only leucine and, to a lesser extent, methionine and alanine were effective, alpha-Ketoisocaproate- and leucine-containing peptides repressed the activity, and leucine also repressed activity in adenyl cyclase-deficient and relaxed strains. Derepression of transhydrogenase followed the removal of leucine from the growth medium and was sensitive to rifampin and chloramphenicol. A phosphoglucoisomerase-deficient strain that was forced to use the hexose monophosphate shunt exclusively had normal levels of transhydrogenase, which was repressed by leucine. Transhydrogenase activity doubled in mutants lacking either of the shunt dehydrogenases but was still repressed by leucine. In strains constitutive for the leucine biosynthetic operon, transhydrogenase was repressed by leucine but in strains livR and lst R, with leucine transport resistant to leucine repression, transhydrogenase was not repressed by leucine. These data suggest that transhydrogenase may have a function in the transport of branched-chain amino acids. In a hisT strain (which has altered leucyl-tRNA), transhydrogeanse was at a repressed level without the addition of leucine, suggesting that leucyl-tRNA may be involved in the regulation.

Promoter- and attenuator-related metabolic regulation of the Salmonella typhimurium histidine operon

Expression of the histidine (his) operon in Salmonella typhimurium was found to be positively correlated with the intracellular level of guanosine tetraphosphate (ppGpp). Limitation for amino acids other than histidine elicited a histidine-independent metabolic regulation of the operon. In bacteria grown at decreased growth rates, his operon expression was metabolically regulated up to a point, after which further decreases in growth rate no longer resulted in further enhancement of operon expression. Studies using strains carrying various regulatory and deletion mutations indicated that metabolic regulation is achieved predominantly by increased RNA chain initiations at the primary (P1) and internal (P2) promoters. Metabolic regulation ordinarly did not involve changes in RNA chain terminations at the attenuator site of the his operon. A model is proposed that involves ppGpp-induced changes in RNA polymerase initiation specificity at particular promoters. A second, special form of metabolic regulation may operate which also is histidine independent, but does involve relief of attenuation.

Escherichia coli mutants with defects in the biosynthesis of 5-methylaminomethyl-2-thio-uridine or 1-methylguanosine in their tRNA

Two tRNA methyltransferase mutants, isolated as described in the accompanying paper (G.R. Björk and K. Kjellin-Stråby, J. Bacteriol. 133:499-207, 1978), are biochemicaaly and genetically characterized. tRNA from mutant IB13 lacks 5-methylaminomethyl-2-thio-uridine in vivo due to a permanently nonfunctional methyltransferase. Thus tRNA from this mutant is a specific substrate for the corresponding tRNA methyltransferase in vitro. In spite of this defect in tRNA, such a mutant is viable. Mutant IB11 is conditionally defective in the biosynthesis of 1-methylguanosine in tRNA due to a temperature-sensitive tRNA (1-methyl-guanosine) methyltransferase. In mutant cells grown at a high temperature, the level of 1-methylguanosine in bulk tRNA is 20% of that of the wild type, demonstrating that in this mutant an 80% deficiency of 1-methylguanosine in tRNA is not lethal. Genetically these two distinct lesions, trmC2, causing 5=methylaminomethyl-2-thio-uridine deficiency, and trmD1, giving a temperature-sensitive tRNA (1-methylguanosine)methyltransferase, are both located between 50 and 61 min on the Escherichia coli chromosome.